A server device includes a tray having a lug, a hard disk unit removably disposed on the tray, and a handle pivotally connected to two opposite sides of the hard disk unit. The lug is formed with a slot thereon to define two inner edges opposite to each other. The handle is provided with a protrusion arranged in the slot. When the handle is rotated towards one end of the hard disk unit, the protrusion is rotated along with the handle to contact and push one of the inner edges of the lug, such that the hard disk unit is restrained by the tray after the hard disk unit is slid in relative to the tray.
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1. A server device, comprising:
a hard disk tray comprising a placing surface and a lug, the lug being disposed on the placing surface and formed with a slot in which two inner edges opposite to each other are defined;
a hard disk unit removably disposed on the placing surface; and
a handle pivotally connected to two opposite sides of the hard disk unit, the handle being substantially in a L-shape with a shorter section substantially perpendicular to a longer section, the shorter section of the handle having a protrusion arranged in the slot,
wherein the protrusion is substantially circular;
wherein, the handle has a first engaging portion, and the hard disk tray has a second engaging portion, and wherein when the handle is rotated towards the one end of the hard disk unit, due to the first engaging portion engaged with the second engaging portion, the hard disk unit is restrained by the hard disk tray,
wherein the first engaging portion comprises a movable member and an elastic member, and the movable member comprises a recess,
wherein the elastic member is disposed between the movable member and a holder portion of the handle,
wherein two opposite ends of the elastic member respectively couple to the movable member and the holder portion of the handle,
wherein the second engaging portion comprises a hook, the hook configured to be inserted into the recess for securing the movable member,
wherein, when the movable member presses the elastic member, the recess escapes from the hook,
wherein the hard disk tray further has a stopper, wherein, when the handle is rotated on the one end of the hard disk unit, the stopper stops the handle from rotating, and
wherein the portions of the inner edges contacted by the protrusion are asymmetric.
2. The server device of
3. The server device of
4. The server device of
5. The server device of
a circuit board which is fixed on the hard disk tray and has a first connector; and the hard disk unit comprising a second connector disposed on the other end of two opposite ends of the hard disk unit, and
wherein when the handle is rotated towards the one end of the hard disk unit, due to the second connector pluggably connected to the first connector, the hard disk unit is restrained by the hard disk tray.
6. The server device of
7. The server device of
8. The server device of
9. The server device of
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This application claims priority to Taiwanese Application Serial Number 103100265, filed Jan. 3, 2014, which is herein incorporated by reference.
Field of Disclosure
The present disclosure relates to a server device. More particularly, the present disclosure relates to a server device with hard disk units.
Description of Related Art
A conventional server device is normally installed with removable hard disks for expanding or enhancing computer functions.
There are several methods for installing a hard disk in a chassis of the server device. For example, screws are used to directly secure two opposite sides of the hard disk on a support bracket of the chassis, respectively; or a slide-rail is used to directly slide the hard disk into a support bracket of the chassis and then screws are used to secure the hard disk thereon.
However, in the aforementioned methods, when the hard disk is mounted on or dismantled from the support bracket of the chassis, many screws needs to be tightened or loosened, thus resulting in complicated procedures and inconvenient operations.
In view of the above, one aspect of the present disclosure is to provide a server device for overcoming the above-mentioned disadvantages existing in the prior art.
According to an embodiment, a server device includes a hard disk tray, a hard disk unit and a handle. The hard disk tray includes a placing surface and a lug. The lug is disposed on the placing surface and is formed with a slot to define two inner edges opposite to each other. The hard disk unit is removably disposed on the placing surface. The handle is pivotally connected to two opposite sides of the hard disk unit, and has a protrusion arranged in the slot.
Thus, when the handle is rotated towards one end of the hard disk unit, the protrusion is rotated along with the handle to contact and push one of the inner edges of the lug, so that the hard disk unit is restrained by the hard disk tray after the hard disk unit is slid in relative to the hard disk tray.
According to one or more embodiments, the hard disk unit includes a main body and a bracket. The bracket is fixed on the main body, and is pivotally connected by the handle.
According to one or more embodiments, the placing surface has a position-limiting hole, and the bracket has a position-limiting projection. Thus, when the handle is rotated towards the end of the hard disk unit, due to the position-limiting projection limited in the position-limiting hole, the hard disk unit is restrained by the hard disk tray.
According to one or more embodiments, the position-limiting hole has a larger area and a smaller area being communicative to the larger hole. Thus, the position-limiting projection is merely limited in the smaller area of the position-limiting hole.
According to one or more embodiments, the server device further comprises a circuit board. The circuit board is fixed on the hard disk tray, and has a first connector. The hard disk unit includes a second connector disposed on the other end of the hard disk unit. Thus, when the handle is rotated towards the end of the hard disk unit, due to the second connector pluggably connected to the first connector, the hard disk unit is restrained by the hard disk tray.
According to one or more embodiments, the handle has a first engaging portion, and the hard disk tray has a second engaging portion. Thus, when the handle is rotated towards the end of the hard disk unit, due to the first engaging portion engaged with the second engaging portion, the hard disk unit is restrained by the hard disk tray.
In the embodiment, specifically, the first engaging portion includes a movable member and an elastic member. The movable member includes a recess; the elastic member connects to the movable member and the handle. The second engaging portion includes a hook. The hook is inserted into the recess for securing the movable member. Thus, when the movable member presses the elastic member, the recess escapes from the hook.
According to one or more embodiments, the handle has a bump, and the hard disk tray has a concave. Thus, when the handle is rotated towards in a direction away from the end of the hard disk unit, the hard disk unit is released by the hard disk tray, wherein the bump is inserted into and limited in the concave.
According to one or more embodiments, two opposite outer sides of the hard disk tray have respective slide rail disposed thereon.
According to one or more embodiments, the hard disk tray has a stopper. Thus, when the handle is rotated on the end of the hard disk unit, the stopper stops the handle from rotating.
As what is disclosed above, comparing to the conventional arts, the solution provided by the present disclosure has advantages and beneficial effects. With the aforementioned solution, the technical improvement and practicability are provided and can be widely applied in the relative industries, wherein the solution provided by the present disclosure at least has the following advantages:
The above description is merely used for illustrating the problems to be resolved, the technical methods for resolving the problems and their efficacies, etc. The specific details of the present disclosure will be explained in the embodiments below and related drawings.
The disclosure may be more fully understood by reading the following detailed description of the embodiment, with reference made to the accompanying drawings as follows:
The following embodiments are disclosed with accompanying diagrams for detailed description. For illustration clarity, many details of practice are explained in the following descriptions. However, it should be understood that these details of practice do not intend to limit the present disclosure. That is, these details of practice are not necessary in parts of embodiments of the present disclosure. Furthermore, for simplifying the drawings, some of the conventional structures and elements are shown with schematic illustrations.
Reference is now made to
According to the embodiment, the server device 100 includes a hard disk tray 200, at least one hard disk unit 400 and at least one handle 500. The hard disk tray 200 includes a placing surface 210 and two lugs 280. The lugs 280 are disposed opposite to each other on the placing surface. Each of the lugs 280 is formed with a slot 290, in which a first inner edge 281 and a second inner edge 282 opposite to each other are defined in the slot 290. The hard disk unit 400 is removably disposed on the placing surface 210 of the hard disk tray 200, and between the lugs 280. The hard disk unit 400 includes a first end 401 and a second end 402 opposite to the first end 401. The handle 500 is provided with two protrusions 540 and two pivot portions 560. The two opposite ends of the handle 500 are respectively pivotally connected to two opposite sides of the hard disk unit 400. The protrusions 540 are respectively located on the two opposite ends of the handle 500, and are respectively arranged in the corresponding slots 290.
Thus, when the handle 500 is rotated towards the first end 401 of the hard disk unit 400, the hard disk unit 400 can be moved in together to transversally slide in relative to the placing surface 210 of the hard disk tray 200, so as to be restrained by the hard disk tray 200. On the other hand, when the handle 500 is rotated towards the second end 402 of the hard disk unit 400 from the first end 401 of the hard disk unit 400, the hard disk unit 400 can be moved in together to transversally slide in relative to the placing surface 210 of the hard disk tray 200, and is released from the restraint of the hard disk tray 200 simultaneously.
In the embodiment, specifically, the hard disk tray 200 further includes a first lateral plate 230 and a second lateral plate 250. The first lateral plate 230 and the second lateral plate 250 are mutually parallel and arranged at two opposite edges of the placing surface 210 thereof, and extend together along an extending direction D1, so that the first lateral plate 230, the second lateral plate 250 and the placing surface 210 define an accommodation space 260.
The accommodation space 260 may allow plural hard disk units 400 to be received therein. The hard disk units 400 are arranged in the accommodation space 260 with a cluster style, for example, the hard disk units 400 are arranged side by side in one single layer in the accommodation space 260 with a generalized array arrangement. Therefore, the hard disk units 400 can be arbitrarily replaced from the hard disk tray 200. However, the present disclosure is not limited to the aforementioned arrangement of the hard disk units. Thus, each of the hard disk units 400 is pivotally connected with a handle 500 thereon.
Every two lugs 280 of the hard disk tray 200 are respectively arranged upright at two opposite outer sides of each of the hard disk units 400 aside, so that each of the hard disk units 400 can be restrained or released by the hard disk tray 200 while the handle 500 rotates.
The server device 100 further includes a storage array backplane 300. The storage array backplane 300 is a circuit board, and is fixed on the hard disk units 220. Moreover, the storage array backplane 300 is provided with at least one first connector 310 (e.g., hard disk connection terminals) for electrically connecting to the hard disk unit 400. In the embodiment, the storage array backplane 300 is disposed upright on the placing surface 210 of the hard disk tray 200, and is arranged between two columns of the hard disk units 400. The storage array backplane 300 has plural first connectors 310, and the first connectors 310 are respectively arranged at intervals on two opposite sides of the storage array backplane 300.
Each of the hard disk units 400 includes a main body 410 and a bracket 430. The main body 410 is substantially rectangular, including two main surfaces 411 which are opposite with each other, two lateral surfaces 412 which are opposite with each other, and two end surfaces 413 which are opposite with each other. Each of the lateral surfaces 412 is adjacently connected to the end surfaces 413, and each of the end surfaces 413 is adjacently connected to the lateral surface 412, such that the main surfaces 411 are surrounded by the end surfaces 413 and the lateral surfaces 412, and the main surfaces 411 are adjacently connected to the end surfaces 413 and the lateral surfaces 412. Because the main body 410 of the hard disk units 400 is a commonly seen hard disk product, a hard disk case is not provided, thereby defining the main body 410 of the hard disk units 400 as a naked disk driver. The first end 401 and the second end 402 are defined as the two end surfaces 413 of the main body 410 of the hard disk units 400. The second end 402 of the hard disk units 400 is provided with at least one second connector 420 (e.g., hard disk connection terminals). The second connector 420 can be a tool-free connector which can be detachably coupled to one of the first connectors 310. The bracket 430 is fixed on the main body 410. For example, a cross-sectional surface of the bracket 430 is in a U-shaped type, and the bracket 430 connects to the lower one of the main surfaces 411 of the main body 410 and the two lateral surfaces 412 adjacent to the lower main surface 411 thereof, and the bracket 430 is secured on the two opposite lateral surfaces 412 of the main body 410 through screws 570.
The handle 500 is in a U-shaped type, and the handle 500 includes two arms 530 and a holder portion 510. The arms 530 respectively locate at two opposite ends of the holder portion 510, and respectively extend towards the bracket 430 along an extending direction D2 (
Furthermore, the handle 500 is provided with a first engaging portion 520. The hard disk tray 200 is provided with a second engaging portion 240 (
In addition, the hard disk tray 200 is slidably disposed in a chassis (not shown in Figure), the hard disk tray 200 is able to either eject out or return in the chassis so as to conveniently assist the hard disk unit 400. Two opposite outer sides (i.e., the first lateral plate 230 and the second lateral plate 250) of the hard disk tray 200 are respectively provided with a slide rail 270 thereon. The slide rails 270 are respectively engaged with corresponding rails (not shown in Figure) arranged in the chassis.
As shown in
Next, as shown in
At this step, as shown in
Also, two opposite sides of the hard disk tray 430 are respectively further provided with a stopper 460. When the holder portion 510 of the handle 500 has already been rotated to the first end 401 of the hard disk unit 400, that is, the holder portion 510 is disposed between the first end 401 of the hard disk unit 400 and the first lateral plate 230, the stopper 460 stops the handle 500 from continually rotating.
It is noted, one having ordinary skill in the art of the disclosure could choose the profile of the first inner edge 281 of the lug 280 to be flat or arc by considering the move extent of the hard disk unit 400 moving towards the storage array backplane 300.
Back to
Substantially, the position-limiting projection 440 includes a head portion 441 and a neck portion 442 connected with each other. The diameter of the head portion 441 is greater than the diameter of the neck portion 442. The area 221A of the larger area 221 is greater than the area 222A of the smaller area 222, but the area 221A of the larger area 221 is smaller than the area of the head portion 441 of the position-limiting projection 440. When the neck portion 442 of the position-limiting projection 440 is moved into the larger area 221 from the smaller area 222 of the position-limiting hole 220, the head portion 441 of the position-limiting projection 440 is limited by the smaller area 222 of the position-limiting hole 220. That is, the head portion 441 of the position-limiting projection 440 cannot leave the position-limiting hole 220 along the axial direction of the smaller area 222 of the position-limiting hole 220. The head portion 441 of the position-limiting projection 440 only can leave the position-limiting hole 220 from the larger area 221 along the axial direction of the larger area 221 of the position-limiting hole 220.
In the embodiment, the position-limiting projection 440 is additionally assembled on the bracket 430. However, the present disclosure is not limited thereto, for example, the position-limiting projection 440 is integrally formed on the bracket 430.
Next, as shown in
It is noted that, as shown in
As shown in
Next, as shown in
It is noted that, one having ordinary skill in the art of the disclosure may optionally design the profile of the second inner edge 282 of the lug 280 as a flat surface or an arc surface by considering the extent of the movement of the hard disk unit 400 towards the first lateral plate 230.
When the user lift sup and removes the hard disk unit 400 from the hard disk tray 200 by the handle 500, in order to prevent the hard disk unit 400 from shaking unexpectedly in relative to the handle 500, referring to
Therefore, as shown in
However, the bracket is not an essential component in the disclosure. In other embodiments, the bracket also can be omitted, and alternatively, the main body is directly pivoted by the handle, and is directly fixed on the hard disk tray, and thus, the aforementioned components on the bracket is directly arranged on the main body.
To sum up, the server device provides a solution for rapidly removing or installing the hard disk units. By merely rotating the handle being pivotally connected to the hard disk unit, the hard disk units can be rapidly removed or installed on the hard disk tray without needing to use extra assembly tools thus enhancing the efficiency and convenience for assembling the hard disk unit
Although the present disclosure has been described in considerable detail with reference to certain embodiments thereof, other embodiments are possible. Therefore, the spirit and scope of the appended claims should not be limited to the description of the embodiments contained herein.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present disclosure without departing from the scope or spirit of the disclosure. In view of the foregoing, it is intended that the present disclosure cover modifications and variations of this disclosure provided they fall within the scope of the following claims.
Chen, Chao-Jung, Chen, Chih-Ming, Jau, Maw-Zan, Tseng, Wei-Cheng
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Jun 06 2014 | CHEN, CHAO-JUNG | QUANTA COMPUTER INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 033064 | /0891 | |
Jun 06 2014 | CHEN, CHIH-MING | QUANTA COMPUTER INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 033064 | /0891 | |
Jun 06 2014 | TSENG, WEI-CHENG | QUANTA COMPUTER INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 033064 | /0891 | |
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